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1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%]

    • Product Name: 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%]
    • Alias: Chlordane
    • Einecs: 215-731-5
    • Mininmum Order: 1 g
    • Factroy Site: Yudu County, Ganzhou, Jiangxi, China
    • Price Inquiry: admin@ascent-chem.com
    • Manufacturer: Ascent Petrochem Holdings Co., Limited
    • CONTACT NOW
    Specifications

    HS Code

    883508

    Chemical Name 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-endo,5,8-endo-dimethanonaphthalene
    Content Percentage >10%
    Molecular Formula C10H6Cl6
    Molecular Weight 373.78 g/mol
    Appearance White to off-white crystalline solid
    Cas Number 309-00-2
    Melting Point 165-187°C
    Solubility In Water Insoluble
    Boiling Point Decomposes before boiling
    Density 1.65 g/cm³
    Odor Mild, musty
    Storage Conditions Store in a cool, dry, well-ventilated area
    Stability Stable under normal conditions
    Hazard Classification Toxic; Environmental Hazard
    Common Name Aldrin

    As an accredited 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%] factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.

    Packing & Storage
    Packing The chemical is packaged in a 500-gram amber glass bottle, sealed with a PTFE-lined cap, and labeled for laboratory use.
    Shipping Shipping for 1,2,3,4,10,10-Hexachloro-1,4,4a,5,8,8a-hexahydro-1,4-endo,5,8-endo-dimethanonaphthalene [Content >10%] must comply with hazardous materials regulations. Package securely in UN-approved containers, label as toxic and environmentally hazardous, include safety data sheets, and follow all transport guidelines for dangerous goods by land, air, or sea.
    Storage Store 1,2,3,4,10,10-Hexachloro-1,4,4a,5,8,8a-hexahydro-1,4-endo,5,8-endo-dimethanonaphthalene (content >10%) in a tightly closed, clearly labeled container in a cool, dry, well-ventilated area away from direct sunlight and incompatible materials (e.g., strong oxidizers). Use secondary containment to prevent leaks. Store in accordance with local regulations and keep away from food, drink, and animal feed.
    Application of 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%]

    Applications of 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%] in Industrial Manufacturing

    As a chemical raw material manufacturer, we supply high-purity 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene for critical applications in the industrial sector. This compound serves specific roles in narrowly-defined chemical synthesis routes for the production of advanced materials, agrochemicals, and specialty chemicals. Below, you will find detailed industrial application scenarios, each supported by relevant standards and integrated into distinct production processes.

    1. Intermediate for Chlordane Synthesis in Agrochemical Manufacturing

    Many agrochemical manufacturers use this compound as a core intermediate in technical-grade chlordane production via closed-system halogenation routes. The compound’s high chlorine content and structured reactivity allow for reliable process control, meeting regulatory specifications in hazardous waste minimization and emission thresholds. The technical process requires precise stoichiometric addition during the chlorination stage, ensuring consistency between batches and alignment with environmental and safety mandates.

    Industry compliance standards

    • US EPA TSCA (Toxic Substances Control Act) Section 5: Pre-Manufacture Notification for pesticide intermediates
    • REACH Annex XVII: Restrictions on the manufacture and use of persistent organic pollutants
    • OSHA 29 CFR 1910.1200: Hazard Communication for workplace safety practices
    • FAO/WHO Manual on Development and Use of FAO and WHO Specifications for Pesticides

    Typical usage ratio

    • 8–12% by weight in relation to the final active ingredient mass, typically adjusted depending on the required technical chlordane purity (72–80%) and batch volume

    Downstream process integration

    • Charged into the halogenation reactor post-solvent addition; introduced as the first halogen carrier prior to further chlorination and stabilization steps

    Final product types

    • Technical chlordane formulations (agricultural soil insecticides, termiticide concentrates)

    2. Precursor for Specialty Chlorinated Resins in Polymer Additive Production

    Producers incorporate this chlorinated hydrocarbon as a precursor in the synthesis of high-performance chlorinated resin additives. Its molecular configuration brings about increased thermal and fire resistance in end-formulated thermoplastics. The material typically enters the polymerization reactor during the initial co-monomer charging, ensuring incorporation into the polymer backbone and yielding enhanced fire-retardant finished goods specified by building and electronics standards.

    Industry compliance standards

    • UL 94: Flammability Standard for Plastics Materials
    • ASTM D2863: Oxygen Index testing for flame retardancy
    • EU RoHS Directive: Restrictions on hazardous flame retardant constituents
    • ISO 9001:2015: Quality Management System for additive manufacturing processes

    Typical usage ratio

    • 3–6% per polymer batch, modulated based on target chlorine incorporation and desired Limiting Oxygen Index (LOI) in the finished resin

    Downstream process integration

    • Blended with co-monomers in the bulk polymerization phase; reacts under high-shear and controlled temperature to form modified resin chains

    Final product types

    • Fire-retardant thermoplastic pellets for cable jackets
    • Flame-resistant insulation foams used in electronics

    3. Raw Material for Synthesis of Chlorinated Cyclodiene Intermediates

    This chlorinated compound acts as a vital building block in producing cyclodiene intermediates. Fine chemical firms employ it in multi-step synthesis aimed at generating active molecules for regulated pesticide and insecticide markets. The feedstock’s high elemental chlorine content supports selective substitution in catalytic or photochlorination reactors, making it a reliable source for specialty cyclodiene derivatives under strict process controls.

    Industry compliance standards

    • EU Regulation No 1107/2009: Approval of active substances for plant protection products
    • Chinese National Standard GB 2763: Maximum residue limits for pesticides in food
    • Good Manufacturing Practice (GMP) for Active Ingredient Synthesis (ICH Q7)
    • Local Environmental Protection Bureaus (EPBs) monitoring for dioxin/furan byproducts

    Typical usage ratio

    • 5–7% per batch during catalyst-loaded synthesis—adjusted according to molecular yield and regulatory batch release criteria

    Downstream process integration

    • Introduced at the primary substrate stage in batch or continuous flow reactors for chlorinated cyclodiene synthesis

    Final product types

    • Pesticide actives for restricted-use agrochemical blends
    • Research-grade chlorinated intermediates for laboratory scale-up

    4. Manufacturing Aid in Industrial-Scale Halogenated Solvent Production

    Large-scale chemical processors utilize this compound to manufacture certain families of halogenated solvents found in degreasing agents and specialist cleaning formulations. Its specific molecular structure facilitates targeted chain modification and increases solvency for chlorinated hydrocarbon mixtures. The material becomes critical during feedstock blending and incremental chlorination, ensuring solvent purity and meeting regulatory residue restrictions in downstream industrial cleaning products.

    Industry compliance standards

    • US EPA 40 CFR Part 261: Identification and listing of hazardous wastes (for chlorinated solvents)
    • REACH Annex XIV: Authorization for the use of certain hazardous substances
    • ISO 14001:2015: Environmental Management Systems for waste and emission minimization
    • ASTM D235: Standard Specification for Mineral Spirits (applies to solvent classification)

    Typical usage ratio

    • 1–4% loading in the precursor blend, adjusted based on solvent volatility and purity specifications for final product applications

    Downstream process integration

    • Added during feedstock charging phase and further chlorinated under controlled pressure; integrated prior to distillation and fractionation to achieve target solvent range

    Final product types

    • Industrial-grade halogenated cleaning solvents
    • Specialty degreasing agents for automotive and electronics sectors

    Free Quote

    Competitive 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%] prices that fit your budget—flexible terms and customized quotes for every order.

    For samples, pricing, or more information, please contact us at +8615365186327 or mail to admin@ascent-chem.com.

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    More Introduction

    1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene [Content >10%]

    A Chemical Manufacturer’s Perspective on Production and Application

    Years of manufacturing experience have made the challenges of producing 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene into a familiar routine. Precision goes into every stage, from sourcing raw materials to achieving a content above 10%. In our facilities, clear parameters keep the product in line with industry needs, and tight specifications maintain a balance of performance with reliability. The chemical community often refers to this compound by its more common trade name, but our focus remains on the compounds themselves, not catchy branding.

    Our Approach to Quality and Consistency

    Raw material selection drives consistency. We rely on established vetting and sampling to minimize unwanted byproducts. Chlorinated hydrocarbon intermediates undergo routine testing using validated chromatography methods to confirm composition, avoiding variable outcomes that trouble less rigorous operators. Nothing frustrates downstream users more than finding batch variation in critical starting points. Years of feedback from technical clients in agriculture, specialty polymers, and fine chemicals taught us to invest in stricter process controls, even if it meant modifying reactor setups or tightening filtration protocols.

    It comes down to trust. Over the years, we’ve learned that analytical transparency matters more than glossy brochures. Technical buyers want clear answers about assay, moisture, and impurities. Control teams routinely cross-check lots against in-house reference standards, so results actually reflect the composition. A clear margin above 10% ensures safety in blending and downstream synthesis, especially in temperature-sensitive applications.

    Understanding Its Place in Synthesis Pathways

    Few chemicals trigger as many production memories as this hexachlorinated intermediate. Decades ago, the shift from single-use custom distillation to scalable, continuous processing established a benchmark in reproducibility. Our production lines adapted, bringing better yields and safer handling practices. Formerly laborious batch operations now run with automation, real-time monitoring, and in-line sampling—these cut risk while boosting purity.

    This compound behaves differently than simpler chlorinated hydrocarbons. Its rigid tricyclic framework resists unwanted isomerization and breakdown, giving it an edge in multi-step synthesis. Users in persistent pesticide production often cite stable yields from our material, especially during periods with regulatory changes or market price fluctuations. Specialty sector clients from advanced materials remark on solubility and processability where some analogs fall short.

    Comparing to Similar Chemicals—What Sets It Apart

    Some outsiders assume 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene is interchangeable with other chlorinated hydrocarbons. Our operations quickly proved otherwise. Tiny shifts in chlorine content or position upend physical and reactivity profiles. Other products in our catalog—like heptachlor or lower-chlorinated naphthalene derivatives—have softer melting points, different solubility characteristics, and unpredictable stability under industrial conditions. Trying to swap those into the same synthesis often costs more in lost product or unexpected byproducts than is worth.

    Our long-term research groups compared degradation profiles during extrusion and polymerization. This hexachloro compound remains more stable than its lower chlorinated cousins, especially when exposed to light or acidic environments. Customers who rely on predictable shelf-life or need to avoid surprises during regulatory testing recognize this advantage. Analytical teams tracked batch stability for over a year in controlled environments—you see minimal change even under suboptimal storage. That becomes critical for industries where logistics or long transport times create trouble.

    Reflections from Manufacturing Floors

    Refining the synthesis of this compound rarely happens by accident. Teams debated everything from agitation rates to optimum cooling periods. In the early days, the process left stubborn residues on vessel walls, creating fire and environmental hazards. Incremental tweaks to solvent ratios and mindful adjustment of reaction temperatures eventually solved these persistent headaches. Old-timers recall scrubber upgrades after evolving VOC standards. Each adaptation brought small improvements in safety, yield, and environmental compliance—few outside the plant realize how many trials it takes for a product to quietly meet its specification line after line.

    One of the most overlooked features remains its low impurity load—thanks to careful distillation and post-reaction workup. Scaling up production brings no shortcuts. Even as volumes increased, process engineers worked closely with QA to ensure downstream users didn’t encounter surprises. Our technical support lines field calls most often about analytical differences between batches found with less scrupulous suppliers—clients discover off-odors, irregular melting behavior, or batch-to-batch drift in performance. Those headaches trace back to loose process control, not some unavoidable trait of the molecule itself.

    Applications: Meeting the Demands of Today’s Chemistries

    Industrial customers drive most of the demand. The largest sector continues to be agrochemicals, particularly as a building block in synthesis of soil treatment products, pest management actives, and sometimes as an intermediate for advanced fungicides. The structure’s persistent nature gives it an ability to serve as a backbone where prolonged field stability matters. Recent years saw new interest from specialty polymer manufacturers. Some clients leverage the molecule’s rigidity for niche high-performance materials, where lesser alternatives don’t make the grade.

    Laboratory reagent distributors and research institutions once formed a minor segment of demand. Requests have shifted as research focuses on new polymer architectures and complex organochlorine syntheses. Field researchers sometimes reach out to discuss observed returns on product use, such as increased shelf-life for blends, or improvements in downstream convertibility. Open communication channels with end users led us to adjust drying and micronization, minimizing dustiness and improving the safety profile of solid forms.

    Handling, Logistics, and Practical Realities

    Shipments follow a careful choreography. Packaging teams work long shifts during peak seasons to keep drums and lined containers sealed, avoiding contamination and witnessing every loading. Regional climate affects shipping routes—a fact few outside logistics appreciate. Hot weather demands different storage protocols to avoid sticking and clumping; cold fronts require antifreeze measures in transit. Repeated customer visits highlighted packaging strength as a source of trust in our supply chain. Integrity of the product doesn’t end at our gate. Every missed detail costs time, money, and sometimes hard-won customer loyalty.

    Distribution is complicated by the compound’s regulatory visibility. Transporting requires alignment with dangerous goods regulations, robust documentation, and sometimes local permits, especially for international routes. On-site safety teams run mock drills and routinely update procedures. Customers who need to comply with country-specific rules benefit from us keeping the paperwork burden as light as possible. Our legal team regularly reviews compliance as part of global export controls.

    Environmental and Workplace Commitments

    Modern manufacturing faces scrutiny over sustainability and emissions. Our plant teams installed improved scrubbers, reduced waste effluent, and shifted to closed systems to control emissions from chlorinated intermediates. Employee training sessions keep everyone updated on safe handling, spill response, and waste minimization. Managers walk the floor, not just to supervise, but to gather feedback on process tweaks, bottlenecks, and safety suggestions.

    Our investments in recycling solvents, reducing water use, and capturing byproducts owe as much to regulatory expectations as to pride in our environment. Sharing technical findings with other local plants helps harmonize standards, reduces risk, and fosters healthy relationships with community watchdog groups. We regularly gather and review data from plant emissions—if improvements surface, adjustments get rolled out. Sticking to tight controls reduced our incident rate compared to industry averages, as documented in annual environmental and safety audits.

    Building for Future Needs

    The market often shifts unexpectedly. Regulatory pressures rise, or customers begin to require new purity levels. Years leading production lines taught us that investing in forward-thinking technology—automation, in-line analytics, greener chemistry—is the only way to keep pace. Continuous improvement became part of our daily dialogue. Too many businesses wait for regulations to force change, but open exchange between production teams and R&D encourages proactive upgrades.

    Clients sometimes pilot new applications—coatings, new formulations, or extended shelf-life blends. Our technical staff supports trials, helping troubleshoot around the properties unique to this hexachloro compound. Dialogue about process compatibility benefits both sides; manufacturers gain insight to optimize production, and clients reach their performance goals more efficiently. This long-term collaboration remains the backbone of progress for both.

    Troubleshooting and Customer Support

    Feedback loops shaped the current state of our offering. Technical teams keep in close contact with users who face specific bottlenecks. Usually, questions revolve around the differences between lots, appearance, or new regulatory compliance measures. Support groups share advice on storage, blending, and analytical verification to help customers navigate unexpected issues. Quick, honest troubleshooting differentiates our support from less experienced suppliers who lack in-depth knowledge of the chemical’s idiosyncrasies.

    We see the greatest improvements come from continuous dialogue with quality control staff at client facilities. Concerns over dust, particle size, or caking in the drums often prompt process adjustments. Sometimes, customer complaints reveal problems in our process that would otherwise go unnoticed until scale becomes unmanageable. We listen first, address the root cause, and share lessons learned back to relevant teams. That’s how product reliability turns into brand loyalty without aggressive advertising.

    Addressing the Challenges of Change

    Transition periods challenge even experienced manufacturers. In the past, changes in regulatory classification for chlorinated intermediates created a scramble for documentation, new MSDS formats, and updated labeling. Plant teams worked overtime to meet requirements without sacrificing product availability. By heading off confusion with clear communication and updated technical sheets, we minimize downstream problems for customers.

    Every upgrade includes pilot testing, analytical method validation, and careful review of storage risks. More than a few times, we’ve chosen to run parallel batches until new process steps fully prove their reliability. Scaling up new changes involves every department, from procurement to engineering—and no step moves forward without broad agreement.

    Lessons from Years in the Field

    A single molecule often unlocks surprising technical advances. Seeing this compound go from tough pilot runs decades back to a streamlined, high-purity mainstay shaped our approach to every product line. Nobody plans every problem—equipment failures, supply disruptions, or regulatory shifts arrive with little warning. Practical experience reveals which shortcuts spell trouble and which tweaks pay off in reliability or yield.

    Focus on deep expertise and open information flows earned trust from technical customers and industry regulators alike. Every batch builds on thousands of hours of collective know-how. The continual feedback loop between our process engineers, front-line workers, and research teams keeps standards high. End users want stability, clear documentation, and honest, fast support when challenges arise. Decades in the business prove that no shortcut can substitute for hands-on knowledge and respect for the product’s strengths and limits.

    The Difference Our Experience Delivers

    Making and supplying 1,2,3,4,10,10-Hexachloro-1,4,4A,5,8,8A-Hexahydro-1,4-Endo,5,8-Endo-Dimethanonaphthalene at content above 10% calls for commitment—commitment to results, safety, and customer outcomes. Chemical manufacturing truly rewards deep attention to process details, steady investment in plant upgrades, and willingness to field tough questions from clients. Our teams respect that every kilogram shipped bears our reputation for quality and safety. That responsibility shapes every decision, from sourcing and synthesis to packaging and support.

    Continual product improvement and a no-nonsense approach to technical support define how we stay on top of industry needs. As customer demands evolve, regulations shift, and technical challenges appear, having decades of direct experience remains the ultimate insurance for those relying on specialty chemicals with stringent requirements. Our practices may not rely on short-term marketing trends or buzzwords, but on tangible results, proven safety, and the kind of reliability that comes only from dedicated manufacturing experience.

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